Lens barrel and imaging device

ABSTRACT

A lens barrel which allows efficient interlock between a cylindrical member such as a moving cam ring and a component such as a viewfinder cam plate or a strobe cam plate, without size-increasing. The lens barrel comprises a first cylindrical member, and a second cylindrical member that is disposed so as to receive the first cylindrical member, and includes a guiding part at an inner circumferential surface thereof. The guiding part includes a groove-form hole part that penetrates the second cylindrical member, and the first cylindrical member includes a follower part that follows the guiding part having the groove-form hole part.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a lens barrel having an imaging lens,and an imaging device such as a camera or the like with the lens barrelprovided therein.

2. Description of the Related Art

Many of the digital cameras which have been widely adopted in recentyears include a viewfinder to allow a user to determine an angle of viewof a subject. Many of these digital cameras also include a strobemechanism to illuminate of the subject with visible light when thesubject is in darkness.

Such digital cameras also generally include a zoom mechanism, andtherefore require an accompanying viewfinder zoom. In cameras includinga zoom mechanism, a zoom-strobe mechanism which changes the angle ofview in a strobe device in conjunction with the zoom magnification ofthe barrel lens is generally known. An example of a camera includingsuch a viewfinder is disclosed in Japanese Laid-Open Patent Publication(Kokai) No. 2004-258167. Further, an example of a camera including azoom-strobe mechanism is disclosed in Japanese Laid-Open PatentPublication (Kokai) No. 2002-182097.

In the technology of Japanese Laid-Open Patent Publication (Kokai) No.2004-258167, a viewfinder cam plate is provided to rotate as a movingcam ring in the zoom barrel rotates, and a viewfinder zoom operation isperformed by way of a viewfinder lens following a cam groove provided inthe viewfinder cam plate. During this operation, the moving cam ring andthe viewfinder cam plate are interlocked using a specially providedprotruding member on the moving cam ring.

In the technology of Japanese Laid-Open Patent Publication (Kokai) No.2002-182097, a strobe cam plate moves as the lens barrel rotates,causing the strobe to move back and forth along an optical axisdirection.

However, in the technology of Japanese Laid-Open Patent Publication(Kokai) No. 2004-258167, not only must a member to allow the moving camring to interlock with the viewfinder cam plate be specially provided onthe moving cam ring, but a groove for fitting the viewfinder cam platein a fixed barrel must be located in a central region of the fixedbarrel. The resulting construction constraints cause a problem in thatthe thickness of the barrel has to increase in the optical axisdirection.

Similarly, in the technology of Japanese Laid-Open Patent Publication(Kokai) No. 2002-182097, not only must a member to allow the moving camring to interlock with the strobe cam plate be specially provided on themoving cam ring, but a groove for fitting the strobe cam plate in afixed barrel must be located in a central region of the fixed barrel.The resulting construction constraints cause a problem in that thethickness of the barrel has to increase in the optical axis direction.

The present invention has been made to solve the above-describedproblems and hence provides a lens barrel and an imaging device whichallow efficient interlock between a cylindrical member such as a movingcam ring and a component such as a viewfinder cam plate or a strobe camplate, without size-increasing.

SUMMARY OF THE INVENTION

In a first aspect of the present invention, there is provided with alens barrel comprising: a first cylindrical member; and a secondcylindrical member that is disposed so as to receive the firstcylindrical member, and includes a guiding part at an innercircumferential surface thereof, wherein the guiding part includes agroove-form hole part that penetrates the second cylindrical member, andthe first cylindrical member includes a follower part that follows theguiding part having the groove-form hole part.

The first cylindrical member can be driven by a driving unit, and theguiding part can be adapted to movably guide the follower part in anoptical axis direction of the lens barrel as the first cylindricalmember is driven by the driving unit.

The lens barrel can comprise a groove-form hole follower part that isfitted in the groove-form hole part and follows the groove-form holepart.

The follower part can be adapted to drive the groove-form hole followerpart via the groove-form hole part.

The guiding part can be adapted to include such a phase as that thegroove-form hole follower part does not interlock with the followerpart.

The first cylindrical member can include a groove-form hole followerdriving part that drives the groove-form hole follower part via thegroove-form hole part.

The guiding part can be adapted to include such a phase as that thegroove-form hole follower part does not interlock with the groove-formhole follower driving unit.

The guiding part can comprise a cam groove, the groove-form hole partcan comprise a through hole, and the follower part can comprise afollower pin.

The groove-form hole follower part can be provided with a viewfinder camthat drives a viewfinder lens.

The groove-form hole follower part can be provided with a strobe camthat drives at least one of a strobe lens and a strobe light generatingunit.

The groove-form hole follower part can be provided with a viewfinder camthat drives a viewfinder lens and at least one of a strobe lens and astrobe light generating unit.

The lens barrel further can comprise a cylindrical member holding partthat holds the second cylindrical member, wherein the second cylindricalmember can be joined to the cylindrical member holding part at aposition where the groove-form hole part is formed.

The groove-form hole follower part can include a rib-form protrusion,the second cylindrical member can include a socket part to accept therib-form protrusion, and the groove-form hole follower part and thesecond cylindrical member can be integrated by the protrusion passingthrough the socket part.

In a second aspect of the present invention, there is provided with animaging device including the above-mentioned lens barrel.

The present invention enables efficient interlock between a cylindricalmember such as a moving cam ring and a component such as a viewfindercam plate or a strobe cam plate, without size-increasing.

The above and other objects, features, and advantages of the inventionwill become more apparent from the following detailed description takenin conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B are external perspective views of a digital camera thatis an imaging device including a barrel lens according to an embodimentof the present invention.

FIGS. 2A to 2C are external views of the digital camera of FIG. 1.

FIG. 3 is an exploded perspective view showing a construction of abarrel lens unit in the digital camera of FIG. 1.

FIG. 4 is an external perspective view showing the barrel lens unit inthe digital camera of FIG. 1.

FIG. 5 is a rear perspective view of a construction of the barrel lensunit in the digital camera of FIG. 1.

FIG. 6 is a cross-sectional view showing a construction of a fixedcylinder of the barrel lens unit in the digital camera of FIG. 1.

FIG. 7 is a block diagram showing an electrical construction of thedigital camera of FIG. 1.

FIG. 8 is a flowchart showing operations from switch-on to completion ofimage capture in the digital camera of FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention will now be described in detail with reference tothe drawings showing preferred embodiments thereof.

<Construction of Imaging Device>

A construction of an imaging device, such as a digital camera, includinga barrel lens according to an embodiment of the present invention isdescribed below with reference to FIGS. 1A and 1B, and FIGS. 2A to 2C.

FIGS. 1A and 1B are external perspective views of a digital camera thatis an imaging device including a barrel lens according to an embodimentof the present invention. FIG. 1A shows a state in which the power isswitched off in the digital camera, and FIG. 1B shows a state in whichthe power is switched on. FIGS. 2A to 2C are external views of thedigital camera of FIG. 1. FIG. 2A is a top view, FIG. 2B is a rear view,and FIG. 2C is a bottom view.

As shown in FIGS. 1A and 1B, a digital camera 14 includes a zoommechanism to enable a degree of magnification to be altered duringimaging. The digital camera 14 includes, on a front surface, aviewfinder 4 for determining a composition of a subject, an auxiliaryoptical unit 19 for assisting a light source when performing photometricranging, a strobe 70, and an imaging lens barrel 11.

As shown in FIGS. 2A to 2C, a release button 15, a power switch button17, and a zoom switch 16 are disposed on an upper surface of the digitalcamera 14. Moreover, a tripod attachment part 27, together with a memorycard drive 42 (see FIG. 7) and battery insertion part (not shown)covered by a built-in card/battery cover 28 are disposed on a bottomsurface of the digital camera 14. Operation buttons 21, 22, 23, 24, 25,and 26 are disposed on a rear surface of the digital camera 14 and allowswitching of various functions. For instance, the operation buttons canbe used to select an imaging mode, a playback mode, a movie imagingmode, or the like as a camera operating mode.

Further, a display 20 that is an LCD, and a viewfinder eyepiece 4 a aredisposed on a rear surface of the digital camera 14. The display 20displays on a screen image data stored in a memory 40 (see FIG. 7) orimage data read from a memory card. When an appropriate mode isselected, the display 20 may further show on the screen a plurality ofreduced-size image data or the like.

<Construction of Lens Barrel Unit>

A description will be given of a construction of the lens barrel unitdisposed in the digital camera 14 of FIG. 1, with reference to FIG. 3,FIG. 4, FIG. 5 and FIG. 6.

FIG. 3 is an exploded perspective view of the construction of the lensbarrel unit in the digital camera 14 of FIG. 1, and FIG. 4 is anexternal perspective view of the lens barrel unit of the digital camera14 of FIG. 1. FIG. 5 is a rear perspective view of a construction of thebarrel lens unit in the digital camera 14 of FIG. 1. FIG. 6 is across-sectional view showing a construction of the fixed cylinder of thebarrel lens unit in the digital camera 14 of FIG. 1.

As shown in FIG. 3 and FIG. 4, the lens barrel unit according to thepresent embodiment includes a moving cam ring 1, and a fixed cylinder 2disposed at an outer circumference of the moving cam ring 1. The movingcam ring 1 is driven by a gear part 1 c shown in FIG. 5 in a moving camring driving unit (not shown), and rotates along an inner circumferenceof the fixed cylinder 2. The moving cam ring driving unit operatesthrough being rotated by a zoom motor driving unit 29 (FIG. 7).

A cam-form cam grooves 2 a are formed in an inner circumferentialsurface of the fixed cylinder 2, and the moving cam ring 1 is caused tomove in the optical axis direction by follower pins 1 a, disposed in themoving cam ring 1, following the cam grooves 2 a. Further, cam grooves 1b are located in an inner circumferential surface of the moving cam ring1. The imaging lens barrel 11 moves in the optical axis direction as aresult of protruding parts (not shown) disposed in the imaging lensbarrel 11 following the cam grooves 1 b.

The cam grooves 2 a are disposed at three locations separatedequiangularly by 120° or the like around the circumference of the fixedcylinder 2. An upper section of each of the cam grooves 2 a has agroove-form hole part (through hole) 2 c formed therein, as shown inFIG. 6. The groove-form hole part 2 c is formed to penetrate a portionof a bottom of the cam groove 2 a.

The digital camera 14 has a built-in zoom viewfinder and a built-in zoomstrobe, and the viewfinder cam plate 3 is provided so as to enable anarc-form sliding on an outer circumference of the fixed cylinder 2 forperforming the respective zoom operations. The viewfinder cam plate 3includes an integrated rib-form coupling pin 3 c (protrusion). A socketpart 2 b is disposed in an extension of the groove-form hole part 2 c ofthe fixed cylinder 2 as shown in FIG. 5. Fitting the coupling pin 3 cinto the socket part 2 b that forms a portion of the groove-form holepart 2 c with the phase matched, in other words, incorporating theviewfinder cam 3 into the fixed cylinder 2 in a bayonet manner enablesthe fixed cylinder 2 and the viewfinder cam plate 3 to be integratelyheld together with accuracy. There is shown in FIG. 5 a state in whichthe viewfinder cam plate 3 is fitted into the fixed cylinder 2. FIG. 5shows that the coupling pin 3 c is fitted into the inner surface of thefixed cylinder 2.

Operations are performed by the moving cam ring 1 interlocking with theviewfinder cam plate 3. However, the interlock is achieved by causing adirect contact between the follower pin 1 a disposed on the moving camring 1 and the coupling pin 3 c of the viewfinder cam plate 3 via thegroove-form hole part 2 c. Alternatively, the moving cam ring 1 may havea viewfinder cam plate driving part 1 d in the vicinity of the followerpin 1 a, and hence the interlock may be achieved by causing a directcontact between the viewfinder cam plate driving part 1 d and thecoupling pin 3 c of the viewfinder cam plate 3 via the groove-form holepart (through hole) 2 c.

As is clear from FIG. 5 and FIG. 6, the groove-form hole part 2 c isprovided up to a middle portion of the cam groove 2 a, and theviewfinder cam plate 3 is adapted to be urged leftwards in FIG. 5(rightwards in FIG. 6) in a fitted state and then stopped at an end faceof the groove-form hole part 2 c.

The follower pin 1 a moves so as to follow the cam shape of the camgroove 2 a. However, the follower pin 1 a is adapted not to contact withthe coupling pin 3 c in a region of the imaging lens barrel 11 extendingwhen the power is switched on in the digital camera 14. When the imaginglens barrel 11 is fully extended, and in a so-called wide-angle region,the follower pin 1 a and the coupling pin 3 c abut against each other.Thereafter, in a zoom region, the follower pin 1 a and the coupling pin3 c move together while abutting against each other.

As described above, in an imaging region for the digital camera 14,which is to say anywhere from a wide-angle imaging position to atelephoto imaging position, the viewfinder cam plate 3 will rotate asthe moving cam ring 1 rotates.

A viewfinder cam 3 a and a strobe cam 3 b are disposed on an uppersurface of the viewfinder cam plate 3. Providing the viewfinder cam 3 aand the strobe cam 3 b on the viewfinder cam plate 3 in this way makesit possible to efficiently construct both the zoom viewfinder and thezoom strobe without size-increasing.

A description will be given of the zoom viewfinder and the zoom strobeaccording to the present embodiment below.

First, a construction of the viewfinder is described below.

As shown in FIG. 3, a viewfinder lens 4 b is fixed to a front surface ofthe digital camera 14. Further, viewfinder lenses 5 and 6 are disposedbehind the viewfinder lens 4 b. The viewfinder lenses 5 and 6 areconstrained to allow only forward and backward movement by a viewfinderstraight motion constrainer 10, and held by a viewfinder lens holdingunit, which is not shown in the drawings. The viewfinder lens 5 allowsviewfinder magnification through movement in the optical axis directionin a so-called zoom viewfinder configuration. A viewfinder lensfollowing part 5 a which follows the viewfinder cam 3 a is provided at abottom part of the viewfinder lens 5 in a tightly integrated manner.

Next, a construction of the strobe is described below.

A strobe lens 7 is fixed to the front surface of the digital camera 14,and a strobe light generating unit 8 is disposed behind the strobe lens7. the strobe light generating unit 8 having a strobe following part 8 aintegrated therein follows the strobe cam 3 b. The strobe lightgenerating unit 8 is constrained to forward and backward movement by astrobe straight motion constrainer 9. Altering the separation betweenthe strobe light generating unit 8 and the strobe lens 7 to therebyalter the angle of light generation makes it possible to construct azoom strobe capable of supporting changes in the angle of view of theimaging lens barrel 11. The strobe lens 7 and the strobe lightgenerating unit 8 are held by a strobe holding part, which is not shownin the drawings.

<Advantages of Lens Barrel Unit according to Present Embodiment>

(1) In the present embodiment, the follower pin 1 a (follower part) ofthe moving cam ring 1 (first cylindrical member) and the coupling pin 3c of the viewfinder cam plate 3 (groove-form hole follower part)directly contact to each other through the groove-form hole part(through hole) 2 c, thereby enabling the moving cam ring 1 and theviewfinder cam plate 3 (groove-form hole follower part) to interlockwith each other. In other words, the coupling pin 3 c of the viewfindercam plate 3 penetrates through the groove-form hole part 2 c (throughhole) disposed in the cam groove 2 a (guiding part) of the fixedcylinder 2 (second cylindrical member) and then engages with thefollower pin 1 a on the inner side of the fixed cylinder 2. This allowsthe viewfinder cam plate 3 to be constructed to move relatively to thefixed cylinder 2. With this construction, it is possible to eliminatethe need for providing, in the conventional manner, a separate member onthe moving cam ring to allow the moving cam ring to interlock with theviewfinder cam plate or strobe cam plate. As a result, the layout issimplified with size-reduction.

(2) When provided in conventional constructions, the through holethrough which the cam plate moves had to be located in a differentposition to the cam groove 2 a due to constructional constraints,resulting in an increased thickness of the lens barrel in the opticalaxis direction. In the present embodiment, on the other hand, thegroove-form hole part 2 c (through hole) is provided directly in the camgroove 2 a, making it possible to accordingly reduce the thickness ofthe lens barrel.

(3) In the present embodiment, since the groove-form through hole part 2c (through hole) is formed in the cam groove 2 a whose dimensions mustbe precisely controlled, a degree of reinforcement is required in thefixed cylinder 2 to avoid deformation in the cam groove 2 a. If thefixed cylinder 2 itself cannot be sufficiently reinforced, deflection ordeformation of the cam groove 2 a can be prevented by joining, in thevicinity of the groove-form hole part 2 c, the fixed cylinder 2 to afixed cylinder holding part 12 for holding a rear surface of the fixedcylinder, using a joint part 13.

As described above, the lens barrel unit of the present embodiment makesit possible to realize a zoom viewfinder and a zoom strobe with a simpleconstruction, a small device size, and an efficient interlock.

The present embodiment is realized for a digital camera was described,but the lens barrel unit construction of the present embodiment can beapplied to a video camera, an analogue camera which make use of silverhalide film, or any other device with a similar lens barrel structure.

<Electrical Construction and Operation of Imaging Device>

A description will be given of the electrical construction and operationof the imaging device including the lens barrel unit of the presentembodiment, with reference to FIG. 7 and FIG. 8.

FIG. 7 is a block diagram of the electrical construction of the digitalcamera 14 of FIG. 1.

As shown in FIG. 7, a control unit 100 of the digital camera 14 isconstructed of a CPU 46, a ROM 45, and a RAM 47. The control unit 100 isconnected via a bus 44 to various components, including the releasebutton 15, the operation buttons 21 to 26, the display 20, the memory40, and the memory card drive 42.

Various functional components including the zoom motor driving unit 29,a focus motor driving unit 31, a shutter driving unit 33, an imagingdevice 37 such as a CCD or CMOS device, and the strobe 7 connect to adriving circuit 43, which also connects to the control unit 100 via thebus 44. The driving circuit 43 controls the driving of the functionalcomponents according to signals from the control unit 100. The ROM 45stores programs for controlling the above-described functionalcomponents, and the RAM 47 stores data required by the control programs.

A description will be given of the overall operation of the digitalcamera of the present embodiment.

When the power is switch from off to on by the user via an operation onthe power switch button 17, the CPU 46 reads the required controlprogram from the ROM 45 and starts an initializing operation. In short,the imaging lens barrel 11 is moved into a predetermined region at whichimaging is possible, the imaging functions are started up, and thedigital camera moves into a standby state.

When the release button 15 for performing image capture is pressed, abrightness of the subject is sensed by the imaging device 37, anddecisions about aperture, shutter speed, and whether the strobe 7 shouldgenerate light are made based on the measured amount of light. Note thatthe user may select whether or not to have the strobe 7 to produce lightusing a preset operation button 22.

The distance to the subject is measured, and the focus motor drivingunit 31 drives a motor to move a focus part 30 to a predetermined focusposition. A shutter part 32 is then open and shut to input the desiredimage on the imaging device 37. The imaging device 37 collects chargedepending on an amount of incident light which in turn depends on anexposure control value. The charge becomes an image signal and isoutputted to an analog signal processing unit 36.

The analog signal processing unit 36 implements analogue processing onthe received image data, and outputs to an A/D converter 38. The A/Dconverter 38 converts the received analog data to digital data. Thedigital data is outputted to a digital signal processing unit 39 anddigital data processing is performed therein. Lastly, the digital datais stored in the memory 40.

In response to an operation on the operation button 23, compressionprocessing is implemented on the data from the memory 40 using JPEG,TIFF or the like by a compression/expansion unit 41. The resulting datais then outputted to and stored on the memory card. In digital cameraswhich do no have a memory corresponding to the memory 40, the digitaldata processed in the digital signal processing unit 39 is outputted tothe compression/expansion unit 41, and stored by the memory card drive42.

The image data stored in the memory 40 and the image data stored by thememory card drive 42 can be expanded by the compression/expansion unit41 and displayed by the display 20 via the bus 44. A user is able tolook at the data on the display 20, and delete unnecessary image datausing an operation on the operation button 24.

Operations on the zoom switch 16 to control the zoom motor driving unit29 via the driving circuit 43, cause lenses in the imaging lens barrel11 to move in the optical axis direction. Operations on the zoom switch16 further enlarge and reduce the stored image displayed on the display20, thereby enabling so-called digital zoom.

A description will be given of operations from switch-on to completionof imaging in a digital camera that is the imaging device having thelens barrel unit according to the present embodiment, with reference toFIG. 8.

FIG. 8 is a flowchart showing operations from switch-on to completion ofimaging in the digital camera of FIG. 1.

When the user switches on the power in the imaging device (step S11),the CPU 46 transmits an instruction to the zoom motor driving unit 29,causing a lens barrel driving motor to rotate clockwise (step S12).Thereafter, a predetermined operation is performed, causing the imaginglens barrel 11 to stop when it is confirmed that the imaging lens barrel11 has moved into the imaging position (step S13). At this point, theimaging lens barrel 11 moves from a state shown in FIG. 1A to a stateshown in FIG. 1B.

Next, when the user switches on the release button 15 (step S14), aphotometric unit measures an amount of light and obtains brightnessinformation about the subject (step 15). If the obtained brightnessinformation indicates that the brightness is higher than a predeterminedlevel (step S16), an aperture part 34 is introduced into the opticalaxis, causing a change in the amount of incident light (step S17). Ifthe obtained brightness information indicates that the brightness islower than a predetermined level, the operation using the aperture part34 is not performed. Instead the aperture part 34 is left in withdrawnstate.

Thereafter, the focus part 30 is moved to a position in which thesubject is in focus (step S18), and image capture is started (step S19).Next, the shutter part 32 is moved from an open state to a closed state(step S20), an amount of light is received, and image capture iscompleted (step S21). Thereafter, the aperture part 34 is withdrawn fromthe optical axis (step S22) and the focus part 30 moved to the initialposition, followed by completing the operations (step S23).

While the present invention has been described with reference toexemplary embodiments, it is to be understood that the invention is notlimited to the disclosed exemplary embodiments. The scope of thefollowing claims is to be accorded the broadest interpretation so as toencompass all modifications, equivalent structures and functions.

This application claims priority from Japanese Patent Application No.2007-009302 filed Jan. 18, 2007, which is hereby incorporated byreference herein in its entirety.

1. A lens barrel comprising: a first cylindrical member; and a secondcylindrical member that is disposed so as to receive the firstcylindrical member, and includes a guiding part at an innercircumferential surface thereof, wherein the guiding part includes agroove-form hole part that penetrates the second cylindrical member, andthe first cylindrical member includes a follower part that follows theguiding part having the groove-form hole part.
 2. A lens barrel asclaimed in claim 1, wherein the first cylindrical member is driven by adriving unit, and the guiding part is adapted to movably guide thefollower part in an optical axis direction of the lens barrel as thefirst cylindrical member is driven by the driving unit.
 3. A lens barrelas claimed in claim 1, further comprising a groove-form hole followerpart that is fitted in the groove-form hole part and follows thegroove-form hole part.
 4. A lens barrel as claimed in claim 3, whereinthe follower part is adapted to drive the groove-form hole follower partvia the groove-form hole part.
 5. A lens barrel as claimed in claim 4,wherein the guiding part is adapted to include such a phase as that thegroove-form hole follower part does not interlock with the followerpart.
 6. A lens barrel as claimed in claim 3, wherein the firstcylindrical member includes a groove-form hole follower driving partthat drives the groove-form hole follower part via the groove-form holepart.
 7. A lens barrel as claimed in claim 6, wherein the guiding partis adapted to include such a phase as that the groove-form hole followerpart does not interlock with the groove-form hole follower driving unit.8. A lens barrel as claimed in claim 1, wherein the guiding partcomprises a cam groove, the groove-form hole part comprises a throughhole, and the follower part comprises a follower pin.
 9. A lens barrelas claimed in claim 3, wherein the groove-form hole follower part isprovided with a viewfinder cam that drives a viewfinder lens.
 10. A lensbarrel as claimed in claim 3, wherein the groove-form hole follower partis provided with a strobe cam that drives at least one of a strobe lensand a strobe light generating unit.
 11. A lens barrel as claimed inclaim 3, wherein the groove-form hole follower part is provided with aviewfinder cam that drives a viewfinder lens and at least one of astrobe lens and a strobe light generating unit.
 12. A lens barrel asclaimed in claim 1, further comprising a cylindrical member holding partthat holds the second cylindrical member, wherein the second cylindricalmember is joined to the cylindrical member holding part at a positionwhere the groove-form hole part is formed.
 13. A lens barrel as claimedin claim 3, wherein the groove-form hole follower part includes arib-form protrusion, the second cylindrical member includes a socketpart to accept the rib-form protrusion, and the groove-form holefollower part and the second cylindrical member are integrated by theprotrusion passing through the socket part.
 14. An imaging deviceincluding the lens barrel as claimed in claim 1.